CN116289225B - Fiber modified based on polyborosiloxane and preparation method thereof - Google Patents

Abstract

The invention provides the use of polyborosiloxane as an impact modifier for fibers, and provides an impact modified fiber comprising a modifier comprising polyborosiloxane, wherein the polyborosiloxane content in the modifier is not less than 50wt%; the polyborosiloxane is siloxane containing a polyboron structure in a polymer chain, wherein the polyboron structure is a structure formed by connecting more than one boron atoms directly through chemical bonds or through rigid primitives; the rigid element contains at least one of the following structures: double bonds, triple bonds, aromatic rings, condensed rings having aromaticity. The modified fiber material based on polyborosiloxane has excellent flexibility, excellent impact resistance and damping performance, is convenient to wear, can effectively avoid the damage of high-speed objects, and has extremely strong application prospect in the field of protection.

Description

Fiber modified based on polyborosiloxane and preparation method thereof

Technical Field

The invention belongs to the field of composite materials, and particularly relates to a fiber modified based on polyborosiloxane and a preparation method thereof.

Background

The development of high performance protective materials, particularly body armor, has received great attention in order to protect the safety of people engaged in high-risk professions. Initial body armor was made from heavy materials such as metal, aluminum alloys, etc., which were mostly inconvenient to wear, greatly restricting human activities. With the advent of high performance fibers (such as aramid Kevlar, ultra High Molecular Weight Polyethylene (UHMWPE)), it has become possible to convert body armor and other protective materials from hard to semi-hard or even soft, and high performance fiber fabrics have been used to produce lighter, more flexible body armor. However, in order to meet the bulletproof requirement, 20-50 layers of high-performance fiber fabrics are often required to be overlapped together, which reduces the comfort and softness of the bulletproof garment and limits the application of the high-performance fibers, so how to improve the impact resistance of the fiber fabrics by modification becomes a very important problem for researchers.

The impact resistance of the fabric is improved by changing the fiber structure or the fiber composition, etc., and is the focus of the research and development of the high-performance bulletproof clothes at present. For example, there are studies reporting that the incorporation of nanomaterials into fabrics not only improves the friction between the fabric fibers, but also greatly increases the impact resistance of the fabric (m.h. malakooti et al composites Part B127 (2017) 222-231). Shear thickening materials (STFs) are a new type of smart materials that are very soft in the normal state and become rigid to digest external forces upon high-speed impact or extrusion. When the external force is eliminated, the material returns to the original soft state, so that the material has extremely strong impact resistance, and is an ideal material for improving the impact resistance of the fabric and simultaneously maintaining the ideal flexibility of the fabric. Lee et al developed STF material/aramid fiber body armor for the first time and made a great contribution in studying the energy absorption mechanism of STF/aramid fiber composite materials (Lee et al journal of materials science 38.13 (2003): 2825-2833.). Polyborosiloxanes are a typical shear thickening material and have great potential for use as impact resistant materials. Zhao et al utilized polyborosiloxane to combine with Kevlar fibers, resulting in a composite fiber material that was far more impact resistant than pure Kevlar fibers (Zhao C et al Smart Materials and Structures,2019,28 (7): 075036).

However, the polyborosiloxane reported in the above-mentioned studies is polyborosiloxane of mono-boron (-Si-O-B-O-) structure, and when the conventional polyborosiloxane is applied to the modification of impact-resistant materials, there is a problem that the stability of the result is poor, and the shear thickening effect thereof is still to be further enhanced. The shear thickening material with more excellent performance is developed and applied to high-performance fiber fabrics to improve the impact resistance, so that the shear thickening material has very important significance.

Disclosure of Invention

In order to solve the problems, the invention provides novel siloxane, namely polyborosiloxane, and the polyborosiloxane is used as a modifier to be added into high-performance polymer fibers, so that the anti-impact performance, damping and anti-vibration performance of the fibers are improved by utilizing the excellent non-Newtonian fluid characteristics (shear thickening characteristics), high network characteristic relaxation time and damping performance of the polyborosiloxane, and the modified fibers with the excellent anti-impact performance are prepared by simple dipping or solution spinning. The basic idea of the invention is to fill the polyborosiloxane-containing material into the fibers, so as to increase the friction force between the fibers, and simultaneously, the super shear thickening effect based on the polyborosiloxane greatly improves the shock resistance of the fibers and keeps the flexibility of the fibers.

The present invention provides the use of polyborosiloxane as an impact modifier for fibers; the polyborosiloxane is siloxane containing a polyboron structure in a polymer chain, wherein the polyboron structure is a structure formed by connecting more than one boron atoms directly through chemical bonds or through rigid primitives; the rigid element contains at least one of the following structures: double bonds, triple bonds, aromatic rings, condensed rings having aromaticity.

The invention also provides a modified fiber which contains a modifier, wherein the modifier comprises polyborosiloxane, and the mass fraction of the polyborosiloxane in the modifier is not less than 50%;

the polyborosiloxane is siloxane containing a polyboron structure in a polymer chain, wherein the polyboron structure is a structure formed by connecting more than one boron atoms directly through chemical bonds or through rigid primitives; the rigid element contains at least one of the following structures: double bonds, triple bonds, aromatic rings, condensed rings having aromaticity.

Further, the above modified fiber is made of a modifier and a fiber polymer, the mass fraction of which is not less than 80%.

Further, the modified fiber is obtained by solution spinning after a modifying agent and a fiber polymer are dissolved in an organic solvent to obtain a spinning solution;

preferably, the concentration of the solute in the spinning solution is not less than 15wt%, and the organic solvent is one or more of toluene, xylene and dimethyl sulfoxide.

Further, the modified fiber is obtained by immersing the fiber made of the fiber polymer in a solution formed by dissolving a modifier in an organic solvent for 5-15 min, taking out, and drying to remove the organic solvent;

preferably, the concentration of the modifier in the solution is 15wt% to 40wt%; the organic solvent is one or more of methanol, ethanol, acetone, tetrahydrofuran, dichloromethane, chloroform, toluene and ethyl acetate.

Further, the modifier also contains damping material and/or filling material; the mass fraction of damping materials in the modifier is less than 50%, and the mass fraction of filling materials is less than 2%;

preferably, the damping material is one or more of polydimethylsiloxane, polyacrylate elastomer and polyurethane elastomer;

and/or the filling material is one or more of silicon dioxide, white carbon black, carbon nanotubes and graphene.

Further, the fiber polymer is one or more of Kevlar fiber, nylon fiber, ultra-high molecular weight polyethylene fiber, aramid fiber, nylon fiber, acrylic fiber, polyester fiber and spandex fiber.

Further, the boron-linked structure is:

B-B structure formed by directly connecting two boron atoms through chemical bond or formed by connecting two boron atoms through benzene ringA structure; preferably, the infrared characteristic peak of the diboron structure is: 1030-1060cm ^-1 The B-B structure of (C) has infrared characteristic absorption peak or 1340-1300cm ^-1 Is->Structural infrared characteristic absorption peak.

Further, in the polyborosiloxane, the mass fraction of the diboron structure is 0.1% -20%.

Still further, the polyborosiloxane is formed by reacting a boron-containing monomer with a silicon substrate, preferably, the mass fraction of the boron-containing monomer is 0.1% -20%.

Further, the boron-containing monomer is a diboronic acid compound, preferably at least one of 1, 4-phenyldiboronic acid, 1, 3-phenyldiboronic acid, biphenyldiboronic acid, anthracene-9, 10-diboronic acid, 2 '-bipyridine-4, 4' -diboronic acid, 2, 5-diboronic thiophene, pyrene-1, 6-diyldiboronic acid, diboronic acid, 2, 6-dimethoxypyridine-3, 5-diboronic acid, bis (catechol) diboronate, dibenzothiophene-2, 8-diboronic acid;

the silicon substrate is at least one of phenyl methyl dichlorosilane, diphenyl dichlorosilane, dimethyl siloxane ring, methyl phenyl siloxane ring, diphenyl siloxane ring, methyl silicone oil, phenyl silicone oil, methyl phenyl silicone oil, hydroxyl-terminated silicone oil, hydroxyl silicone oil, vinyl silicone oil, amino silicone oil, hydrogen-containing silicone oil and fluorine-containing silicone oil.

The invention also provides a preparation method of the modified fiber, which is characterized in that the modified fiber is prepared by an impregnation method or a solution spinning method;

the impregnation method comprises the following steps:

(1) Dissolving a modifier in an organic solvent to form a solution;

(2) Soaking the fiber made of the fiber polymer in the solution obtained in the step (1) for 5-15 min, taking out, and drying to remove the organic solvent.

The solution spinning method comprises the following steps:

(a) The modifier and the fiber polymer are dissolved in an organic solvent to obtain spinning solution;

(b) Defoaming, spinning the solution, and drying to remove the organic solvent.

The invention also provides a fiber fabric, which is woven by the modified fiber.

The invention has the beneficial effects that: the modified fiber material based on polyborosiloxane has excellent flexibility and excellent impact resistance and damping performance. On one hand, the high-speed shock-resistant and damping composite material has excellent shock resistance and damping performance, and can well protect a human body from being damaged by external high-speed objects. Meanwhile, the excellent flexibility can be convenient to wear, the movement of a human body is not limited, and the novel protective fabric has extremely strong application prospect in the field of protection.

It should be apparent that, in light of the foregoing, various modifications, substitutions and alterations can be made herein without departing from the spirit and scope of the invention as defined by the appended claims.

The above-described aspects of the present invention will be described in further detail below with reference to specific embodiments in the form of examples. It should not be understood that the scope of the above subject matter of the present invention is limited to the following examples only. All techniques implemented based on the above description of the invention are within the scope of the invention.

Drawings

FIG. 1 is an infrared spectrum of example 1 and comparative example 1.

Fig. 2 is the rheological properties of example 1 and comparative example 1.

FIG. 3 is a graph showing relaxation times of the network characteristics of example 1 and comparative example 1

Fig. 4 is a schematic illustration of a process for preparing a high impact fiber using an impregnation process.

FIG. 5 shows the variation of force peak magnitude monitored by a force sensor with the number of layers in a low-speed tower falling experiment for preparing polyborosiloxane/acrylic fiber fabrics with different numbers of layers by an immersion method.

FIG. 6 shows the force peak values detected by the force sensor in a low-speed tower falling experiment of composite fiber fabrics obtained by different filling materials with the same layer number or different preparation methods.

Fig. 7 is a stress-strain graph for example 1 at different uniaxial stretching rates.

Detailed Description

The raw materials and equipment used in the invention are all known products and are obtained by purchasing commercial products.

EXAMPLE 1 preparation of polyborosiloxane of the present invention by solution method

0.5g of diboronic acid was dissolved in 5 ml of methanol and stirred uniformly to obtain a methanol solution (1) of diboronic acid. 50g of hydroxyl-terminated silicone oil (molecular weight: 4200 g/mol) was dissolved in 50ml of methanol, and mechanically stirred for 1 hour to obtain a methanol solution (2) of the hydroxyl-terminated silicone oil. Then slowly dripping the diboronic acid solution (1) into the hydroxyl-terminated silicone oil solution (2), and stirring for 3 hours to obtain a uniform and clear reaction precursor solution. The resulting mixed solution was poured into a polytetrafluoroethylene mold, and the solvent was volatilized at room temperature for one day to constant weight. And (3) putting the reaction precursor with the methanol solvent removed into a vacuum oven at 100 ℃ for dehydration reaction for 1 day to obtain the polyborosiloxane material based on the polyboronic structure.

EXAMPLE 2 preparation of polyborosiloxane according to the invention by solution method

0.5g of terephthaloyl acid was dissolved in 5 ml of methanol and stirred uniformly to obtain a methanol solution (1) of terephthaloyl acid. 50g of hydroxyl-terminated silicone oil (molecular weight: 4200 g/mol) was dissolved in 50ml of methanol, and mechanically stirred for 1 hour to obtain a methanol solution (2) of the hydroxyl-terminated silicone oil. Then slowly dripping the terephthal-boric acid solution (1) into the hydroxyl-terminated silicone oil solution (2), and stirring for 3 hours to obtain a uniform and clear reaction precursor solution. The resulting mixed solution was poured into a polytetrafluoroethylene mold, and the solvent was volatilized at room temperature for one day to constant weight. And (3) putting the reaction precursor with the methanol solvent removed into a vacuum oven at 100 ℃ for dehydration reaction for 1 day to obtain the polyborosiloxane material based on the polyboronic structure.

EXAMPLE 3 preparation of polyborosiloxane of the present invention by solution method

0.5g of 2,2 '-bipyridine-4, 4' -diboronic acid was dissolved in 5 ml of dioxane and stirred uniformly to obtain dioxane solution (1) in which 2,2 '-bipyridine-4, 4' -diboronic acid was dissolved. 50g of phenylmethyldichlorosilane was dissolved in 50ml of dioxane, and the solution was mechanically stirred for 1 hour to give a dioxane solution (2) of phenylmethyldichlorosilane. Then, the 2,2 '-bipyridine-4, 4' -diboronic acid solution (1) is slowly added into the phenylmethyldichlorosilane solution (2) in a dropwise manner, and the mixture is stirred for 2 hours to obtain a uniform and clear reaction precursor solution. The resulting mixed solution was poured into a polytetrafluoroethylene mold, and the solvent was volatilized at room temperature for one day to constant weight. And (3) putting the reaction precursor with the dioxane solvent removed into a vacuum oven at 100 ℃ for dehydrochlorination reaction for 1 day to obtain the polyborosiloxane material based on the polyboronic structure.

EXAMPLE 4 preparation of the polyborosiloxane of the present invention by bulk method

10 g of biphenyl diboronic acid and 1000 g of hydroxyl-terminated silicone oil (molecular weight is 18000 g/mol) are added into a kneader for heating and blending (the kneader is set at 100 ℃), and the reaction time is 8 hours, so as to obtain the polyborosiloxane material based on the polyboronic structure.

EXAMPLE 5 preparation of the polyborosiloxane of the present invention by bulk method

5g of biphenyl diboronic acid and 500 g of hydroxyl-terminated methyl phenyl silicone oil (molecular weight is 139000 g/mol) are added into an internal mixer, heated and blended (the internal mixer is set at 120 ℃) and reacted for 6 hours, so as to obtain the polyborosiloxane material based on the polyboronic structure.

EXAMPLE 6 preparation of the polyborosiloxane of the present invention by bulk method

20 g of diboronic acid and 500 g of hydroxyl-terminated methyl phenyl silicone oil (molecular weight is 139000 g/mol) are added into an internal mixer, heated and blended (the internal mixer is set at 120 ℃) and reacted for 6 hours, so as to obtain the polyborosiloxane material based on the polyboronic structure.

EXAMPLE 7 preparation of the modified fiber/modified fiber fabrics of the invention

50g of the polyborosiloxane material prepared in the example 1 is dissolved in 150ml of acetone, after the dissolution is completed, 8cm x 0.05cm acrylic fiber fabric is soaked in the solution for 10min and then taken out, and the solution is placed in a baking oven at 40 ℃ to be dried, so that the single-layer modified fiber fabric is obtained.

To compare the impact resistance of different layer fabrics, 5, 10, 15, 20 layers of polyborosiloxane/acrylic fiber fabrics were prepared (the preparation process is shown in fig. 4).

EXAMPLE 8 preparation of the modified fiber/modified fiber fabrics of the invention

And (3) dissolving 25g of polyborosiloxane prepared in the embodiment 1, 25g of polydimethylsiloxane and 0.5g of platinum curing agent in 150ml of acetone to obtain a mixed solution, soaking 8cm x 0.05cm acrylic fiber fabric in the solution for 10min after the dissolution is completed, taking out the acrylic fiber fabric, and drying the acrylic fiber fabric in an oven at 40 ℃ to obtain the single-layer modified fiber fabric.

Repeating the above operation to prepare 15 layers of polyborosiloxane-polydimethylsiloxane/acrylic fiber fabric, after the solvent is volatilized completely, curing the fabric in a vacuum oven at 80 ℃ for 2-3 hours, and curing the polydimethylsiloxane network to finally obtain 15 layers of polyborosiloxane-polydimethylsiloxane/acrylic fiber fabric.

EXAMPLE 9 preparation of the modified fiber/modified fiber fabrics of the invention

49g of polyborosiloxane prepared in example 1 is dissolved in 150ml of acetone, after dissolution is completed, 1g of white carbon black is added, stirring is carried out for 1h, ultrasound is carried out for 0.5 h, after a uniform filler mixed solution is obtained, 8cm x 0.05cm acrylic fiber fabric is soaked in the solution for 10min and then taken out, and the single-layer modified fiber fabric is obtained after being placed in a baking oven at 40 ℃ for drying.

Repeating the above operation to prepare 15 layers of polyborosiloxane-white carbon black/acrylic fiber fabric.

EXAMPLE 10 preparation of the modified fiber/modified fiber fabrics of the invention

Dissolving acrylic fiber polymer and polyborosiloxane prepared in example 1 in xylene to obtain spinning solution, wherein the mass ratio of acrylic fiber polymer to polyborosiloxane is 4:1, and the acrylic fiber polymer and polyborosiloxane account for 25% of the polymer solution _wt And (3) after vacuum defoamation, obtaining fiber precursor by adopting a solution spinning method, weaving the fiber precursor into an acrylic fiber fabric with the length of 8cm and the length of 0.05cm, and covering 15 layers to obtain the solution spinning polyborosiloxane/acrylic fiber fabric.

Comparative example 1 preparation of polyborosiloxane of conventional monoboro structure by solution method

0.5g of boric acid was dissolved in 5 ml of methanol and stirred uniformly to obtain a methanol solution (1) of boric acid. 50g of hydroxyl-terminated silicone oil (molecular weight: 4200 g/mol) was dissolved in 50ml of methanol, and mechanically stirred for 1 hour to obtain a methanol solution (2) of the hydroxyl-terminated silicone oil. Then slowly dripping the boric acid solution (1) into the hydroxyl-terminated silicone oil solution (2), and stirring for 3 hours to obtain a uniform and clear reaction precursor solution. The resulting mixed solution was poured into a polytetrafluoroethylene mold, and the solvent was volatilized at room temperature for one day to constant weight. And (3) putting the reaction precursor with the methanol solvent removed into a vacuum oven at 100 ℃ for dehydration reaction for 1 day to obtain the polyborosiloxane material based on the monoboro structure.

Comparative example 2 solution method of polyborosiloxane of conventional monoboro structure

0.5g of sodium borate was dissolved in 5 ml of methanol and stirred uniformly to obtain a sodium borate methanol solution (1). 50g of hydroxyl-terminated silicone oil (molecular weight: 4200 g/mol) was dissolved in 50ml of methanol, and mechanically stirred for 1 hour to obtain a methanol solution (2) of the hydroxyl-terminated silicone oil. Then slowly dripping the sodium borate solution (1) into the hydroxyl-terminated silicone oil solution (2), and stirring for 3 hours to obtain a uniform and clear reaction precursor solution. The resulting mixed solution was poured into a polytetrafluoroethylene mold, and the solvent was volatilized at room temperature for one day to constant weight. And (3) putting the reaction precursor with the methanol solvent removed into a vacuum oven at 100 ℃ for dehydration reaction for 1 day to obtain the polyborosiloxane material based on the monoboro structure.

Comparative example 3 preparation of polyborosiloxane of conventional monoboro structure by solution method

0.5g of phenylboronic acid was dissolved in 5 ml of dioxane and stirred uniformly to obtain dioxane solution (1) in which phenylboronic acid was dissolved. 50g of phenylmethyldichlorosilane was dissolved in 50ml of dioxane, and the solution was mechanically stirred for 1 hour to give a dioxane solution (2) of phenylmethyldichlorosilane. Then, the phenylboronic acid solution (1) is slowly added into the phenylmethyldichlorosilane solution (2) in a dropwise manner, and the mixture is stirred for 2 hours to obtain a uniform and clear reaction precursor solution. The resulting mixed solution was poured into a polytetrafluoroethylene mold, and the solvent was volatilized at room temperature for one day to constant weight. And (3) putting the reaction precursor with the dioxane solvent removed into a vacuum oven at 100 ℃ for dehydrochlorination reaction for 1 day to obtain the polyborosiloxane material based on the monoboro structure.

Comparative example 4 preparation of polyborosiloxane of conventional monoboro structure by bulk method

10 g of boric acid and 1000 g of hydroxyl-terminated silicone oil (molecular weight: 18000 g/mol) were added to a kneader for temperature-raising blending (the kneader was set at 100 ℃ C.) and reaction time was 8 hours, to obtain a polyborosiloxane material based on a monoboro structure.

Comparative example 5 preparation of polyborosiloxane of conventional monoboro structure by bulk method

5g of sodium borate and 500 g of hydroxyl-terminated methyl phenyl silicone oil (molecular weight is 139000 g/mol) are added into an internal mixer to be heated and blended (the internal mixer is set at 120 ℃) for 6 hours, and the polyborosiloxane material based on the monoboro structure is obtained.

Comparative example 6 preparation of polyborosiloxane of conventional monoboro structure by bulk method

20 g of boric acid and 500 g of hydroxyl-terminated methyl phenyl silicone oil (molecular weight is 139000 g/mol) are added into an internal mixer to be heated and blended (the internal mixer is set at 120 ℃) for 6 hours, and the polyborosiloxane material based on the monoboro structure is obtained.

Comparative example 7 unmodified virgin fiber web

15 layers of 8cm x 0.05cm acrylic fabric without any material fill were laminated and aligned to give comparative example 1.

Comparative example 8 polyborosiloxane modified fibrous webs of conventional monoboro structure

50g of the traditional polyborosiloxane material with a monoboro structure prepared in comparative example 1 is dissolved in 150ml of acetone, after dissolution is completed, 8cm x 0.05cm acrylic fiber fabric is soaked in the solution for 10min and then taken out, and the obtained product is placed in a baking oven at 40 ℃ to be dried, and the above operation is repeated to prepare 15 layers of polyborosiloxane/acrylic fiber fabric.

Comparative example 9 polydimethyl siloxane modified fibrous webs

50g of polydimethylsiloxane and 0.5g of platinum curing agent are dissolved in 150ml of acetone, after dissolution is completed, 8cm x 0.05cm acrylic fiber fabric is soaked in the solution for 10min and then taken out, and the solution is placed in a baking oven at 40 ℃ for drying, and then the above actions are repeated to prepare 15 layers of polydimethylsiloxane/acrylic fiber fabric. After the solvent is completely volatilized, curing the fabric in a vacuum oven at 80 ℃ for 2-3 hours, and curing the polydimethylsiloxane network to finally obtain 15 layers of polydimethylsiloxane/acrylic fiber fabric.

The beneficial effects of the polyborosiloxane and the modified rubber elastomer material thereof are demonstrated by experimental examples.

Experimental example 1 structural characterization of the polyborosiloxane of the invention

1. The experimental method comprises the following steps: the materials of example 1, comparative example 1 and example 2 were tested for structural characteristics by infrared characterization.

2. Experimental results:

the mass ratio of the diboron structure in example 1 is determined by the ratio of the mass of diboronic acid to the total mass, namely:

thus, the mass fraction of the diboron structure in example 1 was 0.99%. The mass ratio of the mono-boron structure in the corresponding pair of proportion 1 was 0.99%.

As can be seen from the IR characterization of FIG. 1, the materials of example 1 and comparative example 1 both contained a composition of 1340cm ^-1 The Si-O-B characteristic peaks of (C) illustrate that the materials of example 1 and comparative example 1 both incorporate boron-containing units in the polysiloxane chain to form a polyborosiloxane. While 1043cm was contained in the material of example 1 ^-1 The B-B characteristic peaks of (2) illustrate that example 1 successfully synthesizes a polyborosiloxane material having a polyboronic structure. While 1324cm was contained in the material of example 2 ^-1 Characteristic peaks of benzene ring carbon and boron single bond, which illustrate that example 2 successfully synthesizes polyborosiloxane material with polyboronic structure.

Experimental example 2 comparison of the Properties of the polyborosiloxanes of the present invention with conventional polyborosiloxanes

The shear thickening properties of comparative examples 1 and 4 were tested using rheology and as shown in FIG. 2, all of the polyborosiloxanes present a frequency transition point (. Omega.) with a storage modulus equal to the loss modulus _c ) Thus, there is a characteristic relaxation time (τ) of the network _c Inverse of the intersection frequency). Therefore, when the scanning frequency is smaller than ω _c When the integral material is in a viscous fluid state; when the scanning frequency is greater than omega _c When the material is in the elastic solid state, the characteristic relaxation time is the turning point for measuring the mutual transition between the viscous state and the high-elastic state. The frequency turning point of example 1 is lower than that of comparative example 4, that is, the present inventionThe network characteristics of polyborosiloxanes relax for a longer period than conventional polyborosiloxanes (fig. 3). The solid-like performance of the polyborosiloxane is better than that of the traditional polyborosiloxane. In addition, it can be seen from the loss modulus at the overall sweep frequency that as the sweep frequency increases, the loss modulus of all the polyborosiloxane materials decreases and reaches plateau values at high sweep frequencies. The loss modulus of the polyborosiloxane is smaller than that of the traditional polyborosiloxane in the whole scanning frequency range, and the polyborosiloxane is better than that of the traditional polyborosiloxane.

Experimental example 3 impact resistance of modified fiber fabrics of the invention

The impact resistance of the material is tested by utilizing a low-speed tower falling impact test, a standard impactor is released at a specific height, the impact resistance of the material is evaluated by analyzing the impact force applied by the force sensor, and the smaller the indication of the force sensor is, the better the impact resistance of the material is at the moment of being impacted.

We compared the impact resistance of polyborosiloxane/acrylic fiber fabrics with different layers, and it can be seen from fig. 5 that as the number of layers increases, the impact resistance of polyborosiloxane/acrylic fiber fabrics increases, but when the number of layers increases to a certain amount, the impact resistance effect of the increased number of layers does not change much.

The impact resistance of the same number of layers of unfilled acrylic fiber fabric, the inventive polyborosiloxane/acrylic fiber fabric (example 7, example 10), the conventional polyborosiloxane/acrylic fiber fabric (comparative example 8), the polydimethylsiloxane/acrylic fiber fabric (comparative example 9), the polyborosiloxane-polydimethylsiloxane/acrylic fiber fabric (example 8), the polyborosiloxane-white carbon black/acrylic fiber fabric (example 9) were further compared.

The test results are shown in fig. 6. It can be seen that the impact resistance of the acrylic fiber fabric containing the filler material is improved compared to the acrylic fiber fabric without the filler material. However, the fabric containing the polyborosiloxane has better impact resistance than the fabric without the polyborosiloxane. The shock resistance of the polyborosiloxane/acrylic fiber fabric is strongest and is far higher than that of the polydimethylsiloxane/acrylic fiber fabric and the polyborosiloxane/acrylic fiber fabric. After the addition of further modifiers to form the second network structure, the impact resistance remains at a very excellent level, despite a slight decrease. In addition, the fiber fabric filled with the polyborosiloxane obtained by the impregnation method has a slightly higher shock resistance than the fiber fabric filled with the polyborosiloxane obtained by the solution spinning method because the fiber gaps are filled with the material more fully.

Meanwhile, the material of example 1 exhibited excellent flexibility during uniaxial stretching, and elongation at break was more than 600%, as shown in fig. 7.

In summary, the modified fibrous material based on polyborosiloxane of the present invention has excellent flexibility and has excellent impact resistance. On one hand, the excellent shock resistance can well protect a human body from being damaged by external high-speed objects. Meanwhile, the excellent flexibility can be convenient to wear, the movement of a human body is not limited, and the novel protective fabric has extremely strong application prospect in the field of protection.

Claims (14)

1. Use of polyborosiloxane as a fiber impact modifier;

the polyborosiloxane is siloxane containing a polyboron structure in a polymer chain, wherein the polyboron structure is a structure formed by connecting more than one boron atoms directly through chemical bonds or through rigid primitives; the rigid element contains at least one of the following structures: double bonds, triple bonds, aromatic rings, condensed rings having aromaticity.

2. The modified fiber is characterized by comprising a modifier, wherein the modifier comprises polyborosiloxane, and the mass fraction of the polyborosiloxane in the modifier is not less than 50%;

the polyborosiloxane is siloxane containing a polyboron structure in a polymer chain, wherein the polyboron structure is a structure formed by connecting more than one boron atoms directly through chemical bonds or through rigid primitives; the rigid element contains at least one of the following structures: double bonds, triple bonds, aromatic rings, condensed rings having aromaticity.

3. The modified fiber of claim 2, which is made of a modifying agent and a fiber polymer, wherein the mass fraction of the fiber polymer is not less than 80%.

4. A modified fiber according to claim 3, which is obtained by solution spinning after the modifying agent and the fiber polymer are dissolved in an organic solvent to obtain a spinning dope.

5. The modified fiber of claim 4 wherein the concentration of solute in said dope is not less than 15wt%, and said organic solvent is one or more of toluene, xylene, and dimethyl sulfoxide.

6. The modified fiber according to claim 2, wherein the fiber is obtained by immersing the fiber made of the fiber polymer in a solution of the modifying agent dissolved in an organic solvent for 5 to 15 minutes, taking out the fiber, and drying the fiber to remove the organic solvent.

7. The modified fiber of claim 6 wherein the concentration of modifier in said solution is 15wt% to 40wt%; the organic solvent is one or more of methanol, ethanol, acetone, tetrahydrofuran, dichloromethane, chloroform, toluene and ethyl acetate.

8. The modified fiber according to any one of claims 2 to 7, wherein the modifier further comprises a damping material and/or a filler material; the mass fraction of damping materials in the modifier is less than 50%, and the mass fraction of filling materials is less than 2%.

9. The modified fiber of claim 8 wherein the damping material is one or more of polydimethylsiloxane, polyacrylate elastomer, polyurethane elastomer;

and/or the filling material is one or more of silicon dioxide, white carbon black, carbon nanotubes and graphene.

10. The modified fiber according to any one of claims 3 to 6, wherein the fiber polymer is one or more of kevlar fiber, nylon fiber, ultra-high molecular weight polyethylene fiber, aramid fiber, nylon fiber, acrylic fiber, polyester fiber, spandex fiber.

11. The modified fiber of claim 2 wherein the boron-linked structure is:

B-B structure formed by directly connecting two boron atoms through chemical bond or formed by connecting two boron atoms through benzene ringStructure is as follows.

12. The modified fiber of claim 11, wherein the infrared characteristic peak of the diboron structure is: 1030-1060cm ^-1 The B-B structure of (C) has infrared characteristic absorption peak or 1340-1300cm ^-1 A kind of electronic deviceStructural infrared characteristic absorption peak.

13. The method for producing a modified fiber according to any one of claims 2 to 12, characterized in that it is produced by an impregnation method or a solution spinning method;

the impregnation method comprises the following steps:

(1) Dissolving a modifier in an organic solvent to form a solution;

(2) Soaking the fiber made of the fiber polymer in the solution obtained in the step (1) for 5-15 min, taking out, and drying to remove the organic solvent;

the solution spinning method comprises the following steps:

(a) The modifier and the fiber polymer are dissolved in an organic solvent to obtain spinning solution;

(b) Defoaming, spinning the solution, and drying to remove the organic solvent.

14. A fibrous web woven from the modified fiber of any one of claims 2 to 13.